The present invention relates to a thermal overload relay that performs switching-over of contacts upon detection of an overcurrent, in particular to improvement in manipulation structure for returning to a trip state and an initial state.
Patent Document 1, for example, discloses a thermal overload relay operated by detecting an overcurrent running in the main circuit.
The thermal overload relay of Patent Document 1 is described referring to
As shown in
The switching mechanism 4 comprises, as shown in
The contact reversing mechanism 5 comprises a reversing spring 14 fixed at the lower end of the reversing spring to the release lever 8 and extending upwards, a slider 17 linking to the tip of the reversing spring 14 and moving a normally open side movable contact piece 15b and a normally closed side movable contact piece 16a, and a reset bar 18 to manually move the slider 17 to the normal position. The contact reversing mechanism 5 further comprises the above mentioned normally open side movable contact piece 15b and the normally closed side movable contact piece 16a, and a normally open side fixed contact piece 15a and a normally closed side fixed contact piece 16b, the both fixed contact pieces being disposed opposing the movable contact pieces. The reversing spring 14 is a member having a punched window 14a formed by punching a thin spring material and a curved surface with a disc spring shape around the punched window 14a. The reversing spring 14 is curved with a convex towards right hand side in a normal state shown in
When the bimetal 2 bends with the heat generated by the heater 2a due to an overcurrent in the above-described structure, the shifter 3 shifts to the direction indicated by the arrow P in
With progression of the counterclockwise rotation of the release lever 8, the reversing spring 14 deforms while bending with a convex towards the left hand side. The deformation of the reversing spring 14 moves the slider 17 linked to the tip of the reversing spring 14 so as to turn the normally open side movable contact piece 15b and the normally open side fixed contact piece 15a into a closed state and to turn the normally closed side movable contact piece 16a and the normally closed side fixed contact piece 16b into an open state. Based on the information of the closed state of the normally open side movable contact piece 15b and the normally open side fixed contact piece 15a, and the information of the open state of the normally closed side movable contact piece 16a and the normally closed side fixed contact piece 16b conducted by the reversing action of the switching mechanism 4, an electromagnetic contactor (not shown in the figures), for example, connected in the main circuit is opened to interrupt the overcurrent.
After the thermal overload relay is turned to a tripped state and an electric current in the electromagnetic contactor is interrupted, the main bimetal 2 cools down and returns to the initial state. If a reset operation is not conducted, the reversing spring 14 does not deform into the opposite direction with a convex towards the right hand side and the slider 17 does not move to the opposite direction holding the contact reversing mechanism 5 in the state unable to return to the initial state.
In order to return the contact reversing mechanism 5 to the initial state, the reset bar 18 is pushed-in to deform the reversing spring 14 in the opposite direction, thereby moving the slider 17 towards the opposite direction.
There are usually two reset states in the returning operation using the reset bar, i.e. a manual reset state and an automatic reset state, the two states being interchangeable. In the manual reset state, the reset bar is pushed in to return the contact reversing mechanism 5 to the initial state. In the automatic reset state, the reset bar is kept in the pushed-in condition and after the main bimetal 2 is cooled down, the contact reversing mechanism 5 automatically returns to the initial state.
If the reset bar 18 readily changes to the automatic reset state, and the electromagnetic contactor is not provided with self-hold circuit, the motor would restart when the main bimetal cools down after halting of the motor due to trip of the thermal overload relay.
In order to cope with this problem, a technology is known in which a projection linked to a head of the reset bar is provided around a case window for passing through the head of the reset bar. When the reset bar is interchanged from a manual reset state to an automatic reset state, the projection is broken and removed.
Japanese Examined Patent Publication No. H7-001665
In the above-mentioned conventional technology, after breaking and removing the projection provided around the case window, the reset bar needs to be manipulated to change from a manual reset state to an automatic reset state. Thus, a complicated manipulation is required for the automatic resetting.
In addition, the reset bar readily interchanges between the manual reset state and the automatic reset state after breaking and removing the projection from the periphery of the case window, thus there is a possibility of wrong operation of the thermal overload relay.
In view of the above-described unsolved problems in the conventional examples, it is an object of the present invention to provide a thermal overload relay that allows interchange of a reset bar between a manual reset state and automatic reset state with a simple operation at multiple desired times, and avoiding wrong operation of the relay.
Further objects and advantages of the invention will be apparent from the following description of the invention.
In order to accomplish the above object, a thermal overload relay according to the present invention comprises a case; a main bimetal displacing by bending deformation upon detection of an overload current; a release lever working according to displacement of a shifter that displaces following the displacement of the main bimetal; a contact reversing mechanism for changing-over contacts by reversing action caused by rotation of the release lever; and a manipulation structure for manipulating the release lever and the contact reversing mechanism, wherein the all four latter members are disposed in the case. The manipulation structure includes a reset bar for returning the contact reversing mechanism to an initial state, the reset bar partially protruding out of the case and being made to change-over between a manual reset state in which the reset bar is possible to be pushed-in and an automatic reset state in which the reset bar is pushed-in and turned from the manual reset state and held in that state.
The thermal overload relay further comprises a cover attached on the case slidably and capably of covering the manipulation structure, the cover including a reset bar passing window with a configuration of elongated hollow to pass a head of the reset bar and with a longitudinal direction being in the sliding direction of the cover. The reset bar is positioned at one longitudinal end of the reset bar passing window by sliding the cover towards a direction to cover the manipulation structure in the manual reset state and the automatic reset state. The reset bar is held in a. pushed-in state by coupling a bar locking slot formed on an outer circumferential surface of the reset bar and a locking projection formed at the one longitudinal end on the periphery of the reset bar passing window in the automatic reset state.
By the above-stated invention, the operation to change the reset bar to the automatic reset state can be performed only by sliding the cover attached on the case at multiple desired times and the cover holds the reset bar at the pushed-in condition in the automatic reset state. Therefore, any wrong operation is surely avoided in the manual reset state and the automatic reset state.
In the thermal overload relay according to the present invention, the reset bar includes a guiding slot on the circumferential surface thereof at a circumferential position different from the position of the locking slot and the guiding slot of the reset bar couples to the locking projection of the reset bar passing window in a manual reset state and the reset bar is pushed-in with guidance by the guiding slot and the locking projection.
By the above-stated invention, the reset bar is pushed-in smoothly in the manual reset state.
In the thermal overload relay according to the present invention, the manipulation structure comprises an adjusting dial to couple to the release lever for adjusting a setting current, and the cover includes a dial window having a size corresponding to the adjusting part of the adjusting dial; and the dial window faces the adjusting part of the adjusting dial when the reset bar is slid to the other longitudinal end of the reset bar passing window, and the adjusting part of the adjusting dial is covered by the slid cover in the manual reset state and the automatic reset state.
By the above-stated invention, the cover covers the adjusting part of the adjusting dial in the condition the reset bar has been changed to the manual reset state and the automatic reset state, obstructing adjusting operation for a setting current. Therefore, a wrong operation of the thermal overload relay is obviated.
The thermal overload relay according to the present invention further comprises a window for state-indication and manual trip operation, in the vicinity of the reset bar, for manually reversing the contact reversing mechanism and confirming operational state of the contact reversing mechanism, wherein the window for state-indication and manual trip operation is not covered by the cover in the condition of the reset bar slid to the other longitudinal end of the reset bar passing window that is farthest from the coupling projection of the cover, and the window for state-indication and manual trip operation is covered by the cover in the manual reset state and the automatic reset state.
By the above-stated invention, the cover covers the window for state-indication and manual trip operation in the condition the reset bar has been changed to the manual reset state and the automatic reset state, inhibiting a manual trip operation. Therefore, a wrong operation of the thermal overload relay is obviated.
In the thermal overload relay according to the present invention, the cover is formed of a transparent material.
By the above-stated invention, even when some parts of the manipulation structure are covered by the cover, the operation condition of the contact reversing mechanism at that time can be confirmed by visual observation.
A thermal overload relay according to the present invention allows changing operation of the reset bar to an automatic reset state at a desired time only by sliding the cover attached to the case, and holding the reset bar at a pushed-in condition by the cover in the automatic reset state. Therefore, any wrong operation is surely obviated in the manual reset state and the automatic reset state.
a) is a drawing showing the contact reversing mechanism and a normally open contact (a-contact) that are in an initial state;
b) is a drawing showing the contact reversing mechanism and a normally open contact (a-contact) that are in a tripped state;
a) is a drawing showing the contact reversing mechanism and a normally closed contact (b-contact) that are in an initial state;
b) is a drawing showing the contact reversing mechanism and a normally closed contact (b-contact) that are in a tripped state;
a) and 9(b) are perspective views showing the front side and back side, respectively, of a cover that is slidably coupled to a case of the thermal overload relay;
The following describes the best mode of some preferred examples of embodiment according to the invention in detail with reference to the accompanying drawings. The parts of the embodiment examples of the invention similar to the parts in
A thermal overload relay of the embodiment as shown in Fig. comprises a manipulation structure 45 at the top of an insulator case 1, the manipulation structure 45 being composed of an adjusting part 11b of an adjusting dial 11, a reset bar 43 for reset operation of a contact reversing mechanism, which will be described afterwards, and a window 44 for state-indication and manual trip operation for a contact reversing mechanism. The thermal overload relay also comprises a slide cover 46 attached on the top of the insulator case 1, the slide cover 46 being slid according to an operation of the manipulation structure 45.
In the insulator case 1, disposed are, as shown in
The adjusting mechanism 20 comprises an adjusting link 22, a release lever 23 rotatably supported by the adjusting link 22, and a temperature compensation bimetal 24 fixed to the release lever 23 and linked to the shifter 3.
The adjusting link 22 is composed, as shown in
The link support 25, including a pair of bearing holes 25a1 formed in the upper portion thereof, has a pair of opposing plates 25a opposing each other and a connection plate 25c connecting the pair of opposing plates 25a and forming an opening 25b. The leg part 26 extends downwards from one of the pair of opposing plates 25a and includes a bearing hole 26a in the lower portion thereof.
A support shaft 27 is provided to protrude from the inner wall at the lower part of the insulator case 1 into an inside of the insulator case 1 as shown in
The release lever 23 has, as shown in
The contact reversing mechanism 21 is disposed in the insulator case 1 and comprises, as shown in
The interlock plate 34 has, as shown in
In the opposite side to the a-contact 38 with respect to the interlock plate 34, as shown in
The reset bar 43, as shown in
The reset bar 43, as shown in
Now referring to
The slide cover 46 is slid corresponding to the manipulation of the manipulation structure 45 composed of the adjusting part 11b of the adjusting dial 11, the reset bar 43 and the window for state-indication and manual trip operation 44. The slide cover 46 is made of a transparent resin. In the slide cover 46, a reset bar passing window 46a and an adjusting dial operation window 46b are formed as shown in
The reset bar passing window 46a has a configuration elongated in the direction as same as direction of extension of the slide guides 46c, 46d, and has a reset bar locking projection 46e formed at one longitudinal end of the periphery of the window.
Now operation of the embodiment of the thermal overload relay will be described in the following.
At first, description of the operation of the thermal overload relay is made in the case of the reset bar 43 in the manual reset state.
Referring to
In this configuration, the adjusting dial operation window 46b of the slide cover 46 just corresponds to the adjusting part 11b of the adjusting dial 11. Consequently, the adjusting part 11b of the adjusting dial 11 can be rotated by using a tool such as a screw driver inserted through the adjusting dial operation window 46b to change the rotation angle of the release lever 23, thereby adjusting a setting current.
Since the slide cover 46 is not covering the window for state-indication and manual trip operation, the thermal overload relay can be tentatively turned to the manually tripped state by manipulation on the trip operation beam 34a using a tool such as a screw driver inserted through the window for state-indication and manual trip operation 44. In this changing process, the tool is coupled to the trip operation bean 34a and the interlock plate 34 in the initial state as shown in
Then, as shown in
After the slide cover 46 is slid until the reset bar coupling protrusion 46e couples to the guiding slot 43d to change the reset bar 43 to the manual reset state, the adjusting dial operation window 46b comes out of the correspondence to the adjusting part lib of the adjusting dial 11 and the window for state-indication and manual trip operation 44 is covered by the slide cover 46. In this manual reset state, thus, adjustment of setting current by the adjusting dial 11 and manipulation to the manual trip cannot be conducted.
When an overcurrent flows in the thermal overload relay of this embodiment, the main bimetal 2 is bent with the heat generated in the heater 2a by the overcurrent. Displacement of the free end of the main bimetal 2 displaces the sifter 3 in the direction of arrow Q indicated in
In progression of clockwise rotation of the release lever 23, at the moment the pushing force of the reversing spring pushing part 23f exceeds the spring force of the reversing spring 36, the movable plate 35 starts to perform a reversing action around the lower part 35a. Accompanying the reversing action of the movable plate 35, the interlock plate 34, receiving the reversing action of the movable plate 35 transmitted through the first linking pin 39a, rotates around the support shaft 33 (see
As a result, the fixed contact piece 38a and the movable contact piece 38b of the a-contact 38 in the open state shown in
Then, in the condition of the main bimetal 2 returned to the original configuration from the bent state after interruption of the main circuit current, the reset bar 43 in the manual reset state is pushed-in downwards as indicated by the arrow in
With this manual reset operation of the reset bar 43, the reset block 43c exerts a resetting force through the a-contact side leaf spring 37 on the movable plate 35 in the tripped state shown in
In order to change the reset bar 43 in the manual reset state to the automatic reset state on the other hand, referring to
Then, as shown in
In the circumstance the slide cover 46 has been moved so that the reset bar 43 becomes in the automatic reset state, the adjusting dial operation window 46b does not position at a place corresponding to the adjusting part 11b of the adjusting dial 11, and the window for state-indication and manual trip operation 44 is covered by the slide cover 46. Consequently, in the automatic reset state, too, like in the manual reset state, adjustment of a setting current by the adjusting dial 11 and manipulation for manual trip are obstructed.
When an overcurrent flows in this condition, bend of the main bimetal 2 is transmitted through the shifter 3 and the temperature compensation bimetal 24 causing rotation of the release lever 23, which in turn pushes the reversing spring 36 via the reversing spring pushing part 23f. Reversing action of the reversing spring 36 is obstructed by the .first liking pin 39a of the interlock plate 34, on which the larger radius portion 43c1 of the reset block 43c is abutting. As a consequence, the a-contact 38 and the b-contact 42 comes to a state where the distance between the fixed contact piece 38a and the movable contact piece 38b of the a-contact 38 is small and the distance between the fixed contact piece 42a and the movable contact piece 42b of the b-contact 42 is small.
In the condition the reset bar 43 has been changed to the automatic reset state, the reversing operation of the reversing spring 36 does not complete even due to an overcurrent, and after cooling down of the main bimetal 2, the reversing spring 36 automatically returns to the initial state.
Now, effects of the present invention will be described in the following.
For making the reset bar 43 in the manual reset state, the reset bar 43 is made to project out of the reset bar passing window 46a formed with an elongated hollow shape in the slide cover 46 at the position furthest from the reset bar coupling projection 46e. For changing the reset bar 43 to the automatic reset state, the reset bar 43 is pushed-in and turned so that the locking slot 43b formed on the circumferential surface of the reset bar 43 faces the reset bar coupling projection 46e on the peripheral surface of the reset bar passing window 46a at the one longitudinal end. Then, the slide cover 46 is slid so that the coupling between the locking slot 43b and the reset bar coupling projection 46e is established. In this state, the reset bar 43 is held in the pushed-in condition. Therefore, the reset bar 43 is manipulated simply to change from the manual reset state to the automatic reset state.
The manipulation for changing-over between the manual reset state and the automatic reset state of the reset bar 43 can be conducted at any desired time only sliding the slide cover 46. Confirmation can be made whether the reset bar 43 is in a condition of not pushed-in or pushed-in and held in that condition. Therefore, wrong operation can be obviated between the manual reset state and the automatic reset state.
In the process of pushing-in of the reset bar 43 in the manual reset state, the reset bar 43 is guided by the reset bar coupling projection 46e on the reset bar passing window 46a coupled to the guiding slot 43d of the reset bar 43. Therefore, the pushing-in action of the reset bar 43 is performed smoothly.
In the condition the reset bar 43 has been change to the automatic reset state, the slide cover 46 covers the adjusting part 11b of the adjusting dial 11 and the window 44 for state-indication and manual trip operation, inhibiting adjusting action of a setting current by the adjusting dial 11 and manipulation for manual trip. Therefore, wrong operation is obviated in the thermal overload relay.
In addition, the slide cover 46 is made of a transparent material. Consequently, the adjustment value of the adjusting part lib can be checked even if the adjusting part lib of the adjusting dial 11 is covered with the slide cover, and the operating state of the contact reversing mechanism 21 (specifically interlock plate 34) at that time can be confirmed even when the window 44 for state-indication and manual trip operation is covered with the slide cover.
The disclosure of Japanese Patent Application No. 2009-0793.92 filed on Mar. 27, 2009 is incorporated as a reference.
While the invention has been explained with reference to the specific embodiments of the invention, the explanation is illustrative and the invention is limited only by the appended claims.
Number | Date | Country | Kind |
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2009-079392 | Mar 2009 | JP | national |